US1372738A - Method and machine for forming teeth in saws - Google Patents

Method and machine for forming teeth in saws Download PDF

Info

Publication number
US1372738A
US1372738A US288093A US28809319A US1372738A US 1372738 A US1372738 A US 1372738A US 288093 A US288093 A US 288093A US 28809319 A US28809319 A US 28809319A US 1372738 A US1372738 A US 1372738A
Authority
US
United States
Prior art keywords
teeth
blanks
cutter
machine
shaft
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US288093A
Inventor
Swan O Bjornberg
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to US288093A priority Critical patent/US1372738A/en
Application granted granted Critical
Publication of US1372738A publication Critical patent/US1372738A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23DPLANING; SLOTTING; SHEARING; BROACHING; SAWING; FILING; SCRAPING; LIKE OPERATIONS FOR WORKING METAL BY REMOVING MATERIAL, NOT OTHERWISE PROVIDED FOR
    • B23D65/00Making tools for sawing machines or sawing devices for use in cutting any kind of material
    • B23D65/04Making saw teeth by milling
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T409/00Gear cutting, milling, or planing
    • Y10T409/30Milling
    • Y10T409/303752Process
    • Y10T409/303808Process including infeeding
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T409/00Gear cutting, milling, or planing
    • Y10T409/30Milling
    • Y10T409/304536Milling including means to infeed work to cutter

Definitions

  • This invention relates to the manufacture of saws. More particularly, it relates to improvements in the method and means for forming the teeth in saw blades.
  • the method and machine hereinafter described is particularly adapted for cutting the teeth in hack-saw blades, although the invention may be employed in the formation of teeth in saws of other types.
  • One object of this invention is to provide practical method by which each saw tooth in its formation, is subjected to precisely the same treatment as the other teeth in the saw whereby uniform teeth are formed.
  • a plurality of blanks are usually clamped face to face in block formation, with their longitudinal edges in a common plane.
  • the cutter is then caused to pass along the plane of the edges in a direction transversely of the blanks, and thus cut teeth in all of the blanks durin one cutting operation.
  • Another object of this invention is to prov1de an unproved method whereby teeth may be formed in an indefinite number of blanks without interrupting the cutting operation.
  • Another object is to provide an improved method of manipulating the blanks during the teeth forming operation, whereby teeth are formed in successive blanks by a cutting action which progresses lengthwise of the blanks.
  • Another object is to provide a method of presenting the blanks to arotating milling cutter in such a manner that the teeth are formed by a cutting action which progresses lengthwise of the blanks and also from the edge of the blanks toward the base of the finished teeth.
  • Another object is to provide a continuously operating machine for forming teeth in an indefinite number of saw blanks.
  • Another object is to provide a mechanism for delivering the blanks to the cutter in such manner that the teeth are successively formed by a cutting action which progresses from the edge of the blank toward the base of the teeth.
  • Another object is to provide improved means for feeding a blank through the cutting zone.
  • Another object is to provide improved means for adjustably supporting a cutter.
  • Another object is to provide an improved drive mechanism for a cutter, which will permit various adjustments of the cutter.
  • Tn practising the method of the present invention an indefinite number of blanks are successively subjected to the action of a continuously rotating cutter, having a series of spirally arranged milling teeth.
  • the blanks are firmly clamped and advanced lengthwise in a direction transversely of the path of travel of the milling teeth, and in such manner that during the advance of the blanks the teeth out deeper and deeper into the edge thereof, until saw teeth of full depth have been formed.
  • the spiral arrangement of the milling teeth permit a continuous advance of the blanks during the cutting operation.
  • Figure 1 is a plan view of the machine showing in dotted lines the position of the cutter
  • Fig. 2 is a longitudinal sectionthrough the machine, illustrating the manner of mounting the feeddrums. In thisfigure the cutting mechanism is illustrated in elevation;
  • Fig. 3 is a section on a somewhat larger scale taken on the line 33 of Fig. 1; r
  • Fig. 1 is a section taken on the line 4 4 of Fig. 3
  • Figs. 5 and 6 are a bottom plan and side elevation, respectively, ofthe cutter illustrating theprogressive action thereof on the saw blanks;
  • Figs. 7 and 8 illustrate diagrammatically the respective positions of the blank with respect to the cutter as it enters andgleaves the zone of cutting operation;
  • Fig. 9 is a fragmentary end elevation. of the machine illustrating particularly the means for driving the various parts;
  • Fig. 10 is a horizontal section taken on linelO-10. of Fig. 9;
  • Fig. 11 is a horizontal section taken on line11 lfof Fig. 9;
  • Fig. 12 is a Vertical section taken on line 1212 of Fig. 10.
  • the frame of the machine comprises a bed or table 10, having an upstanding bracket 1.1 for supporting the cutting mechanism to be hereinafter described.
  • the bed or'table 10 may be supported in any convenient manner.
  • a pair of rotatable feed drums 12 and 13 are mounted in spaced relation upon the table 10.
  • Ear-h drum is provided with a vertical peripheral wall 14 and a projecting annular flange 15, for receiving and sup porting an endless feed-belt 16, which passes around the drums.
  • the feed drum 12 is keyed to a spindle 17 mounted for rotation in a slidable'bearing block 18, fitted in a slide way 19 formed in the top of the table 10.
  • Suitable springs 20 interposed between the blocks and one end wall of the slide way press the block in such direction as to maintain proper tension in the feed-belt 16.
  • the spindle 17 is retained in proper position in the block by any convenient means, such as a nut 21.
  • a fiat faced boss 22 projecting upwardly from the face of the table forms a broadfaced seat for the drum 12, and prevents a deviation of the drum fromits normal plane of rotation.
  • the other drum 13 rests upon a broad seat afforded by an annular protuberance 23 projecting upwardly from the face of the table.
  • This drum is keyed to and is driven by a stub-shaft 24 mounted for rotation insuit able fixed bearings 25 formed in the table.
  • Thestub-shaft 24 passes through the table and is provided at its lower end with a worm-gear 24: secured thereto.
  • Rotation is imparted to the worm-gear 25 and hence to the drum 13 by means of a worm 26 secured to one end of a driven shaft 27, mounted in suitable bearing brackets 28 extending from the under side of the table; The other end of this shaft extends through a suitable bearing 29 in the vertical wall of the machine bed or table, and is driven by means of gears 30, 31, from the vertical shaft 32.
  • a blank supporting. feedtable has been provided. preferably consists of a flat plate 33 supported in a horizontal position by means of a bracket 3% bolted or otherwise secured to the machine bed or table 10. As shown, the feed table extends parallel to the run-of the belt, with the delivery end thereof immediately adjacent the peripheral wall of the feed-drum 13, at a point where the'belt makes initial contact therewith.
  • the blanks are positioned on edge on the plate 33, and are moved preferably one at a time until the, advanced end there 7 of is pinched between the traveling belt and
  • the feed table nevavse ring 35 seated in an annular recess 36 in the peripheral wall of the drum serves as a backing for the blank during the cutting operation, the teeth of the cutter passing through the blank and through the upper front corner of this ring.
  • the height of the feed plate 33 is such that the blanks are delivered to the feed mechanism with the upper edge thereof substantially flush with the upper surface of ring 35.
  • the feed belt is of such width however that its upper edge is not engaged by the cutter.
  • the cutting mechanism includes a continuously driven hob or formed helical cutter 37 mounted for rotation about a fixed axis.
  • the cutter is preferably cylindrical in form, and is provided with a series of milling teeth spirally arranged around the periphery thereof.
  • the cutter is preferably positioned immediately above the path of travel of the blanks, with its axis of rotation in a vertical plane substantially tangential to the periphery of the drum 13 as indicated in Fig. 1 of the drawing. Cutters of various shapes and sizes may be employed depending upon the character of the work to be produced.
  • the teeth may be arranged to form a single, double or triple thread.
  • Adjustable means is therefore provided for supporting the cutter in proper working position.
  • This means may assume various forms. In the present instance, however, this means includes an L-shaped bracket 38 mounted for vertical adjustment upon the upstanding bracket 11, previously referred to.
  • bracket 11 is provided with vertically extending laterally projecting flanges 39, which fit in correspondingly shaped vertical grooves 40 in the vertical leg of the L-shaped bracket 38.
  • A. vertical adjusting screw 41 is rotatably fixed in a bearing plate 42 secured to the bracket 11, and is threaded through a nut 43 fixed to the bracket 38. The projecting end of this screw may be suitably fashioned to receive a convenient tool for rotating the screw to effect a vertical adjustment of the bracket.
  • the under face of the L-shaped bracket 38 is provided with a horizontally extending dovetail projection 44 seated in a correspondingly shaped recess 44 in a plate 45.
  • a vertical shaft 47 is rotatably supported by the plate 45.
  • the shaft extends upwardly through an opening 48 formed near one end of the plate.
  • the upper end 49 of this opening is somewhat enlarged to form a seat or shoulder for a lock washer 50 screwed onto the threaded end of the shaft.
  • A. jam-nut 51 may be employed to lock the washer in place.
  • a second plate 52 is supported beneath plate 45 for angular adjustment about the axis of shaft 47.
  • This plate is provided near one end with a suitable bore to receive the shaft 47.
  • a miter pinion 53 pinned or otherwise secured to the shaft holds this end of the plate in position.
  • the other end of the plate 52 is provided with an car 54 carrying a pin 55, which projects upwardly through an arcuate adjusting slot 56 (Fig. 1) in a flange 57 projecting from the plate 45.
  • a nut 58 screwed onto the end of the pin supports this end of the plate 52 and firmly clamps the same in adjusting position.
  • the nut 58 may be made integral with the pin as a unitary cap screw having a reduced threaded shank screwing into the ear 54.
  • Suitable bearing brackets 59 and 60 extend downwardly from plate 52 to support the cutter spindle 61.
  • Bearing bracket 59 is preferably cast integral with the plate, while bracket 60 is preferably removably attached thereto by means of a sliding dovetail connection 62. (Fig. 2.)
  • the bracket may be secured against sliding movement by any convenient means such as a set screw. This construction permits ready removal of the bracket for purposes of assembly, and also permits adjustment of the parts, so that cutters of various lengths may be employed.
  • the cutter 37 is rigidly clamped on the spindle 61 between the collar 63 and the clamping sleeve 64 by means of a nut 65 threaded on the spindle.
  • the spindle is driven by means of a miter pinion 66 secured thereto and meshing with the miter pinion 5% hereinbefore mentioned secured to shaft 4
  • the upper end of shaft 47 is carried by the horizontally adjustable plate 45, which is, in turn, supported by the vertically adjustable bracket 38.
  • Means is therefore provided for maintaining the lower end of the shaft in proper working position for any adjustment of the upper end thereof.
  • this means includes a horizontally adjustable bearing block 67 mounted for sliding adjustment in the slot 68, formed in a suitable bracket 69, secured to the machine bed. @ne side of the slot is formed by a yielding arm 70 (see Figs. 10 and 11), which maybe drawn into firm clamping engagement with the block by means of the clamp screw 71.
  • the shaft 47 is rotatably j ournaled in block 67 and is permitted longitudinal sliding movement therein.
  • a pinion is supported in horizontal position upon a collar (3 resting upon the slide block 67, and is slidably keyed to the shaft 47.
  • Shaft 32 previously referred to is rotatably supported in a suitable bearing bracket 74 secured to the machine bed, and asses through a bearing in the bracket 69.
  • gear Wheel 75 secured to this shaft is operably connected with the pinion 72 by means of the adjustably mounted intermediate gears 76 and 77.
  • These gears are carried by a lever 78 mounted upon bracket 69, for an gular adjustment about shaft 32 as its center.
  • the smaller gear 76 constantly meshes with gear wheel 75 on shaft 82, irrespective of the position of the lever 78.
  • the lever 78 is fixed insuch adjusted position as to cause the larger gear 77 to mesh with pinion 72 on shaft 417.
  • Such construction permits an operative driving connection between the shafts 32 and 47, no matter what position of adjustment is assumed by the latter shaft.
  • Lever 78 is fixed in adjusted position by means of a bolt and nut connection 79 extending through the lever and through an arcuate slot 80 formed in the bracket 69.
  • a convenient means for mounting the gears 76 and 77 upon the lever is shown in detail in Fig. 12.
  • the gears are keyed together by means of a sleeve 81, having a rib 82 projecting into a key-way in each. of the gears.
  • Sleeve 81 is mounted .for rotation upon a spacing sleeve 83.
  • the parts are held in assembled relation upon the lever 78 by means of a bolt and nut connection 84, passing through the sleeve 83 and through an adjusting slot 85 in the lever.
  • the purpose of the slot is to permit adjustment of the gears 76 and 77 toward and from the gear wheel 75, so that gears of varying sizes may be employed.
  • An additionalslot '86 is shown in the lever 78 to take the gear supporting bolt 84-, in case a very large gear 77 is employed. This affords a very broad range of adjustment of the parts.
  • the cutter supporting plate 52 is angularly adjusted, and plate 45 horizontally adjusted, to bring the axis of the cutter in a vertical plane tangential to the path of the work at a point immediately beneath the far end of the cutter (see Fig. 1).
  • the L-shaped bracket is then vertically adjusted to gage the depth of the cut.
  • Power is then delivered to the machine through shaft 47 from any convenient source causing rotation of the cutter in a clockwise direction (Fig. 2) and rotation of feed drum '13 in a counterclockwise di rection (Fig. 1).
  • the blanks are then withdrawn one at time by the action of the feed belt and drum and advanced lengthwise beneath the rotating cutter along the curved path defined by the periphery of the drum.
  • the speed at which the blanks advance is dependent upon the gear ratio between shaft 47 and32 and is made to correspond with the spiral advance of the cutting teeth during the rotation of the cutter.
  • each blank During the advance of each blank, it enters beneath the cutter in a position offset from the axis thereof, as indicated in Figs. 5, 6, and 7. At this point the cutting teeth engage only the extreme upper edge of the blank. During its lengthwise progress,
  • the path of movement of the blade being such that the notch forming operation progresses from the outer edge of the blade toward the base of the finished teeth.
  • a hob having a series of spirally arranged milling teeth
  • means for effecting a relative longitudinal movement between said hob and a saw blank means for rotating said hob to out teeth in the edge of the blank during such relative movement.
  • a machine for cutting teeth saw blanks the combination of a rotatable hob having a series of spirally arranged milling teeth, means for causing a lengthwise advance of a blank along a definite path, means for supporting said hob with its milling teeth extending across said path and means for rotating said hob during the advance of said blank to cut teeth in the edge thereof.

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Sawing (AREA)

Description

s. 0. BJORNBERG.
METHOD AND MACHINE FOR FORMING TEETH IN SAWS.
Patent/e61 M31229, 19210 APPLICATION FILED APR. 7, 1919. 1,372,738, 7
3 SHEE'lS-SHEET I.
s. o.v BJORNBERG. v METHOD AND MACHINE'FQR FORMING TEETH IN SAWS. I
' W" Patented MamZQ), 192110 Y a suns-sum 2'.
/ I WMWM S. O. BJORNBERG.
METHOD AND MACHINE FOR FORMING TEETH lN SAWS.
APPLICATION FILED APR.7.1919.
31 372,? 880 Patented Mar. 29, 1921;.
3 SHEE'|'SSHEET 3.
SWAN O. BJORNBEBG, 0F CHICAGO, ILLINOIS.
METHOD AND MACHINE FOR FORMING TEETH IN SAWS.
Application filed April 7, 1919.
To all whom it may conccm:
Be it known that I, SWAN O. BJORNBERG, a citizen of the United States, residing at Chicago, in the county of Cook and State of Illinois, have invented a certain new and useful Improvement in Methods and Machines for Forming Teeth in Saws, of which the following is a full, clear, concise, and exact description, reference being had to the accompanying drawings, forming a part of this specification.
This invention relates to the manufacture of saws. More particularly, it relates to improvements in the method and means for forming the teeth in saw blades.
The method and machine hereinafter described is particularly adapted for cutting the teeth in hack-saw blades, although the invention may be employed in the formation of teeth in saws of other types.
Heretofore, it has been common practice to form teeth in hack-saw blanks by the use of a milling cutter, which is caused to pass transversely across the edge of the blank while the blank is firmly clamped in fixed position. Notches are thus formed in the edge of the blank, leaving upstanding teeth. It is essential that the teeth of the saw be uniformly shaped and uniformly spaced. By this old method the shape and position of the several teeth produced depends upon the shape and relative position of the several lines of cutting teeth comprising the cutter. In order to provide a cutter of sufiicient length to form all the teeth in a saw blank at one operation, the cutter is built up of a plurality of cylindrical sections rigidly secured together. Any inaccuracy in the positioning of the several sections, results in the production of inaccurately shaped teeth. This not infrequently happens and the saws thus formed must often be discarded.
One object of this invention is to provide practical method by which each saw tooth in its formation, is subjected to precisely the same treatment as the other teeth in the saw whereby uniform teeth are formed.
In carrying out the old method, a plurality of blanks are usually clamped face to face in block formation, with their longitudinal edges in a common plane. The cutter is then caused to pass along the plane of the edges in a direction transversely of the blanks, and thus cut teeth in all of the blanks durin one cutting operation.
Specification of Letters Patent.
Patented Mar. as, 1921.
Serial No. 288,093.
The number of blanks which can be thus operated upon at one time is limited, however, because of the difiiculty in holding them 1n proper working position. Furthermore, considerable care must be exercised to see that the blanks are properly positioned and to insure that each is firmly clamped. Thus, by this old method considerable time 1s consumed in the removal of the cut blanks from the machine after one cutting operatlon, and in replacing uncut blanks therein preparatory to the next succeeding operaion.
Another object of this invention is to prov1de an unproved method whereby teeth may be formed in an indefinite number of blanks without interrupting the cutting operation.
Another object is to provide an improved method of manipulating the blanks during the teeth forming operation, whereby teeth are formed in successive blanks by a cutting action which progresses lengthwise of the blanks.
Another object is to provide a method of presenting the blanks to arotating milling cutter in such a manner that the teeth are formed by a cutting action which progresses lengthwise of the blanks and also from the edge of the blanks toward the base of the finished teeth.
Another object is to provide a continuously operating machine for forming teeth in an indefinite number of saw blanks.
Another object is to provide a mechanism for delivering the blanks to the cutter in such manner that the teeth are successively formed by a cutting action which progresses from the edge of the blank toward the base of the teeth.
Another object is to provide improved means for feeding a blank through the cutting zone.
Another object is to provide improved means for adjustably supporting a cutter.
Another object is to provide an improved drive mechanism for a cutter, which will permit various adjustments of the cutter.
Other objects and advantages will hereinafter appear.
Tn practising the method of the present invention an indefinite number of blanks are successively subjected to the action of a continuously rotating cutter, having a series of spirally arranged milling teeth. The blanks are firmly clamped and advanced lengthwise in a direction transversely of the path of travel of the milling teeth, and in such manner that during the advance of the blanks the teeth out deeper and deeper into the edge thereof, until saw teeth of full depth have been formed. The spiral arrangement of the milling teeth permit a continuous advance of the blanks during the cutting operation.
A more complete understanding of the method may be had from the following de scription of the construction and operation of a machine made in accordance with this invention. i
A machine designed for carrying out the method is illustrated in the accompanying drawing.
The views of the drawings are as follows:
Figure 1 is a plan view of the machine showing in dotted lines the position of the cutter;
Fig. 2 is a longitudinal sectionthrough the machine, illustrating the manner of mounting the feeddrums. In thisfigure the cutting mechanism is illustrated in elevation;
Fig. 3 is a section on a somewhat larger scale taken on the line 33 of Fig. 1; r
Fig. 1 is a section taken on the line 4 4 of Fig. 3
Figs. 5 and 6 are a bottom plan and side elevation, respectively, ofthe cutter illustrating theprogressive action thereof on the saw blanks;
Figs. 7 and 8 illustrate diagrammatically the respective positions of the blank with respect to the cutter as it enters andgleaves the zone of cutting operation; V
Fig. 9 is a fragmentary end elevation. of the machine illustrating particularly the means for driving the various parts;
Fig. 10 is a horizontal section taken on linelO-10. of Fig. 9;
Fig. 11 is a horizontal section taken on line11 lfof Fig. 9;
Fig. 12 is a Vertical section taken on line 1212 of Fig. 10. The frame of the machine comprises a bed or table 10, having an upstanding bracket 1.1 for supporting the cutting mechanism to be hereinafter described. The bed or'table 10 may be supported in any convenient manner.
A pair of rotatable feed drums 12 and 13 are mounted in spaced relation upon the table 10. Ear-h drum is provided with a vertical peripheral wall 14 and a projecting annular flange 15, for receiving and sup porting an endless feed-belt 16, which passes around the drums. The feed drum 12 is keyed to a spindle 17 mounted for rotation in a slidable'bearing block 18, fitted in a slide way 19 formed in the top of the table 10. Suitable springs 20 interposed between the blocks and one end wall of the slide way press the block in such direction as to maintain proper tension in the feed-belt 16. The spindle 17 is retained in proper position in the block by any convenient means, such as a nut 21. A fiat faced boss 22 projecting upwardly from the face of the table forms a broadfaced seat for the drum 12, and prevents a deviation of the drum fromits normal plane of rotation.
The other drum 13 rests upon a broad seat afforded by an annular protuberance 23 projecting upwardly from the face of the table. This drum is keyed to and is driven by a stub-shaft 24 mounted for rotation insuit able fixed bearings 25 formed in the table. Thestub-shaft 24 passes through the table and is provided at its lower end with a worm-gear 24: secured thereto.
Rotation is imparted to the worm-gear 25 and hence to the drum 13 by means of a worm 26 secured to one end of a driven shaft 27, mounted in suitable bearing brackets 28 extending from the under side of the table; The other end of this shaft extends through a suitable bearing 29 in the vertical wall of the machine bed or table, and is driven by means of gears 30, 31, from the vertical shaft 32.
The feed-belt 16 and feed drums 12 and 13 cooperate to form a simple and effective means for firmly clamping and carrying the saw blanks in properly clamped condition through the zone of the cutting operation. In order to deliver the. blanks to this conveying mechanism, a blank supporting. feedtable has been provided. preferably consists of a flat plate 33 supported in a horizontal position by means of a bracket 3% bolted or otherwise secured to the machine bed or table 10. As shown, the feed table extends parallel to the run-of the belt, with the delivery end thereof immediately adjacent the peripheral wall of the feed-drum 13, at a point where the'belt makes initial contact therewith.
The operation of the parts thus far, described is as follow A continuous rota: ion'is imparted to the feed-drum from the shaft 32, through the gears 30, 31, shaft 21, worm 26, worm gear 25, and stub-shaft 24.
This causes a continuous travel of the feedbelt 16, and consequent rotation of feed-1 drum 12. The blanks are positioned on edge on the plate 33, and are moved preferably one at a time until the, advanced end there 7 of is pinched between the traveling belt and The feed table nevavse ring 35 seated in an annular recess 36 in the peripheral wall of the drum serves as a backing for the blank during the cutting operation, the teeth of the cutter passing through the blank and through the upper front corner of this ring.
The height of the feed plate 33 is such that the blanks are delivered to the feed mechanism with the upper edge thereof substantially flush with the upper surface of ring 35. The feed belt is of such width however that its upper edge is not engaged by the cutter.
The cutting mechanism includes a continuously driven hob or formed helical cutter 37 mounted for rotation about a fixed axis. The cutter is preferably cylindrical in form, and is provided with a series of milling teeth spirally arranged around the periphery thereof. The cutter is preferably positioned immediately above the path of travel of the blanks, with its axis of rotation in a vertical plane substantially tangential to the periphery of the drum 13 as indicated in Fig. 1 of the drawing. Cutters of various shapes and sizes may be employed depending upon the character of the work to be produced. Furthermore the teeth may be arranged to form a single, double or triple thread.
Adjustable means is therefore provided for supporting the cutter in proper working position. This means may assume various forms. In the present instance, however, this means includes an L-shaped bracket 38 mounted for vertical adjustment upon the upstanding bracket 11, previously referred to. For this purpose bracket 11 is provided with vertically extending laterally projecting flanges 39, which fit in correspondingly shaped vertical grooves 40 in the vertical leg of the L-shaped bracket 38. A. vertical adjusting screw 41 is rotatably fixed in a bearing plate 42 secured to the bracket 11, and is threaded through a nut 43 fixed to the bracket 38. The projecting end of this screw may be suitably fashioned to receive a convenient tool for rotating the screw to effect a vertical adjustment of the bracket.
As shown more particularly in Fig. 4 the under face of the L-shaped bracket 38 is provided with a horizontally extending dovetail projection 44 seated in a correspondingly shaped recess 44 in a plate 45. An
l o ad usting screw 46 is employed to effect a horizontal adjustment of plate relative to bracket 38, in a manner similar to the adjustment just described.
A vertical shaft 47 is rotatably supported by the plate 45. The shaft extends upwardly through an opening 48 formed near one end of the plate. As shown, the upper end 49 of this opening is somewhat enlarged to form a seat or shoulder for a lock washer 50 screwed onto the threaded end of the shaft. A. jam-nut 51 may be employed to lock the washer in place.
A second plate 52 is supported beneath plate 45 for angular adjustment about the axis of shaft 47. This plate is provided near one end with a suitable bore to receive the shaft 47. A miter pinion 53 pinned or otherwise secured to the shaft holds this end of the plate in position. The other end of the plate 52 is provided with an car 54 carrying a pin 55, which projects upwardly through an arcuate adjusting slot 56 (Fig. 1) in a flange 57 projecting from the plate 45. A nut 58 screwed onto the end of the pin supports this end of the plate 52 and firmly clamps the same in adjusting position. The nut 58 may be made integral with the pin as a unitary cap screw having a reduced threaded shank screwing into the ear 54.
Suitable bearing brackets 59 and 60 extend downwardly from plate 52 to support the cutter spindle 61. Bearing bracket 59 is preferably cast integral with the plate, while bracket 60 is preferably removably attached thereto by means of a sliding dovetail connection 62. (Fig. 2.) The bracket may be secured against sliding movement by any convenient means such as a set screw. This construction permits ready removal of the bracket for purposes of assembly, and also permits adjustment of the parts, so that cutters of various lengths may be employed.
The cutter 37 is rigidly clamped on the spindle 61 between the collar 63 and the clamping sleeve 64 by means of a nut 65 threaded on the spindle. The spindle is driven by means of a miter pinion 66 secured thereto and meshing with the miter pinion 5% hereinbefore mentioned secured to shaft 4 As previously pointed out, the upper end of shaft 47 is carried by the horizontally adjustable plate 45, which is, in turn, supported by the vertically adjustable bracket 38. Means is therefore provided for maintaining the lower end of the shaft in proper working position for any adjustment of the upper end thereof. In the present instance, this means includes a horizontally adjustable bearing block 67 mounted for sliding adjustment in the slot 68, formed in a suitable bracket 69, secured to the machine bed. @ne side of the slot is formed by a yielding arm 70 (see Figs. 10 and 11), which maybe drawn into firm clamping engagement with the block by means of the clamp screw 71.
The shaft 47 is rotatably j ournaled in block 67 and is permitted longitudinal sliding movement therein. A pinion is suported in horizontal position upon a collar (3 resting upon the slide block 67, and is slidably keyed to the shaft 47.
Shaft 32 previously referred to is rotatably supported in a suitable bearing bracket 74 secured to the machine bed, and asses through a bearing in the bracket 69. gear Wheel 75 secured to this shaft is operably connected with the pinion 72 by means of the adjustably mounted intermediate gears 76 and 77. These gears are carried by a lever 78 mounted upon bracket 69, for an gular adjustment about shaft 32 as its center. The smaller gear 76 constantly meshes with gear wheel 75 on shaft 82, irrespective of the position of the lever 78. The lever 78is fixed insuch adjusted position as to cause the larger gear 77 to mesh with pinion 72 on shaft 417. Such construction permits an operative driving connection between the shafts 32 and 47, no matter what position of adjustment is assumed by the latter shaft.
Lever 78 is fixed in adjusted position by means of a bolt and nut connection 79 extending through the lever and through an arcuate slot 80 formed in the bracket 69.
A convenient means for mounting the gears 76 and 77 upon the lever is shown in detail in Fig. 12. The gears are keyed together by means of a sleeve 81, having a rib 82 projecting into a key-way in each. of the gears. Sleeve 81 is mounted .for rotation upon a spacing sleeve 83. The parts are held in assembled relation upon the lever 78 by means of a bolt and nut connection 84, passing through the sleeve 83 and through an adjusting slot 85 in the lever. The purpose of the slot is to permit adjustment of the gears 76 and 77 toward and from the gear wheel 75, so that gears of varying sizes may be employed. Thus the proper gear ratio may be obtained between the shafts 32 and 17. An additionalslot '86 is shown in the lever 78 to take the gear supporting bolt 84-, in case a very large gear 77 is employed. This affords a very broad range of adjustment of the parts.
The operation of the entire mechanism will now be briefly described. The cutter supporting plate 52 is angularly adjusted, and plate 45 horizontally adjusted, to bring the axis of the cutter in a vertical plane tangential to the path of the work at a point immediately beneath the far end of the cutter (see Fig. 1). The L-shaped bracket is then vertically adjusted to gage the depth of the cut.
Power is then delivered to the machine through shaft 47 from any convenient source causing rotation of the cutter in a clockwise direction (Fig. 2) and rotation of feed drum '13 in a counterclockwise di rection (Fig. 1). The blanks are then withdrawn one at time by the action of the feed belt and drum and advanced lengthwise beneath the rotating cutter along the curved path defined by the periphery of the drum. The speed at which the blanks advance is dependent upon the gear ratio between shaft 47 and32 and is made to correspond with the spiral advance of the cutting teeth during the rotation of the cutter.
During the advance of each blank, it enters beneath the cutter in a position offset from the axis thereof, as indicated in Figs. 5, 6, and 7. At this point the cutting teeth engage only the extreme upper edge of the blank. During its lengthwise progress,
however, the blank. gradually approachesthe machine hereinbefore' described, without departing from or sacrificing any of the advantages of the present invention, as de- 7 fined in the claims appended hereto.
I claim:
1. Themethod of forming teeth in hacksaw blades and the like, which consists in firmly clamping the blade in position with one edge thereof exposed, moving the blade lengthwise while in the clamped condition, and during such lengthwise movement forming successive notches in the exposed edge thereof to form teeth of the desired shape,
the path of movement of the blade being such that the notch forming operation progresses from the outer edge of the blade toward the base of the finished teeth.
2. The method of forming teeth in hacksaw blades and the like, which consists in firmly clamping the blade in a curved con dition with one edge exposed, causing a lengthwise advance of the blade while in such curved condition, and forming successive notches in the exposed edge thereof while the blade is in motion to formteeth of the desired shape, the path of movement of the blade being such that the notch forming operation progresses from the outer edge of the blade toward the baseof the finished teeth.
3. The method of forming teeth in hacksaw blades and the like, which consistsin causing the blade to travel in a lengthwise direction along a curved path, firmly lamping the blade during its lengthwise travel, and cutting successive notches in the edge thereof to form teeth of the desired shape, by a cutting operation, which progresses from the edge of the blade toward the base of the finished teeth. 7
4; in a machine for forming teeth in hacksaw blades and the like, the combination of a teeth-forming member, of a mechanism for continuously moving a succession of saw blades longitudinally past said teeth forming member to successively and progres- The position of the blank Cir sively present the longitudinal edges of said blades to the action of said teeth forming member.
5. In a machine of the class described, the combination of a continuously rotating milling utter, and continuous conveyer means supporting saw blades end to end to deliver them one at a time to the action of said milling cutter.
6. In machine of the class described, the combination of a continuously rotating milling cutter having teeth spirally arranged, of continuous conveyer mechanism for firmly clamping a plurality of saw-blanks end to end and moving the same continuously in a direction longitudinally of the cutter and toward the axis of rotation thereof, so as to present the longitudinal edges of the blanks to the progressive action of the cutter.
7. In a machine of the class described, the combination of a mechanism for firmly clamping a saw-blank and advancing the same along a curved path, a continuously rotating milling cutter having cutting teeth spirally arranged, and means for supporting said milling cutter in position with its axis of rotation in a vertical plane tangential to the path of movement of the saw blanks, so that the action of said cutter progresses from the extreme outer edge of the blank toward the base of the finished teeth.
8. In a machine for cutting teeth in saw blanks, the combination of a hob having a series of spirally arranged milling teeth, means for effecting a relative longitudinal movement between said hob and a saw blank, and means for rotating said hob to out teeth in the edge of the blank during such relative movement.
9. In a machine for cutting teeth 1n saw blanks the combination of a rotatable hob having a series of spirally arranged milling teeth, means for causing a lengthwise advance of a blank along a definite path, means for supporting said hob with its milling teeth extending across said path and means for rotating said hob during the advance of said blank to cut teeth in the edge thereof.
10. In a machine for cutting teeth in saw blanks the combination with a teeth-forming member of an endless conveyer for presenting the blanks successively to the action of the teeth-forming member.
11. In a machine of the class described, the combination of a hob for cutting teeth in saw blanks, mechanism for advancing the blanks lengthwise of said hob, means for rotating said hob, and means connected with said first named means for actuating said mechanism to advance the blanks at a speed corresponding to the speed of rotation of said hob.
12. In a machine of the class described the combination of a holder for a saw blank, mechanism for cutting notches in the blank to form saw teeth, and a support for said mechanism including means for vertically adjusting said mechanism, means for horizontally adjusting said mechanism, and means for angularly adjusting said mechanism.
13. The combination of a rotating milling cutter, mechanism for presenting blanks to the action of said cutter, a drive shaft for said cutter, adjustable means for supporting said cutter and said drive shaft, means for actuating said blank presenting mechanism, and adjustable means for operatively connecting said actuating means with said shaft at any position of adjustment of said shaft.
1 The combination of a hob for forming teeth in saw blanks, mechanism for presenting blanks to the action of said hob, means for rotating said hob, and means for actuating said blank presenting mechanism, said means including interchangeable gearing operatively connected with said first named means whereby the speed of advance of the blanks may be controlled.
15. In a machine for forming teeth in hack-saw blades and the like, the combination with means for clamping a blade and feeding the same in a lengthwise direction along a predetermined path, of a teeth forming member operable during the advance of the blade to form successive teeth in the edg thereof by an action which progresses from the edge of the blade toward the base of the finished teeth.
In witness whereof, I hereunto subscribe my name this 3d day of April, A. D. 1919.
SWAN O. BJORNBERG.
US288093A 1919-04-07 1919-04-07 Method and machine for forming teeth in saws Expired - Lifetime US1372738A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US288093A US1372738A (en) 1919-04-07 1919-04-07 Method and machine for forming teeth in saws

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US288093A US1372738A (en) 1919-04-07 1919-04-07 Method and machine for forming teeth in saws

Publications (1)

Publication Number Publication Date
US1372738A true US1372738A (en) 1921-03-29

Family

ID=23105706

Family Applications (1)

Application Number Title Priority Date Filing Date
US288093A Expired - Lifetime US1372738A (en) 1919-04-07 1919-04-07 Method and machine for forming teeth in saws

Country Status (1)

Country Link
US (1) US1372738A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2984128A (en) * 1959-08-20 1961-05-16 Fitchburg Engineering Corp Machine for milling teeth
DE3939205A1 (en) * 1988-11-30 1990-05-31 Sandvik Ab METHOD AND DEVICE FOR GRINDING SAWS
US20070144318A1 (en) * 2005-12-22 2007-06-28 Fu-Zin Agriculture Supply Inc. Method and apparatus for automatically forming teeth of a straight saw

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2984128A (en) * 1959-08-20 1961-05-16 Fitchburg Engineering Corp Machine for milling teeth
DE3939205A1 (en) * 1988-11-30 1990-05-31 Sandvik Ab METHOD AND DEVICE FOR GRINDING SAWS
US5016497A (en) * 1988-11-30 1991-05-21 Sandvik Ab Method and apparatus for grinding teeth in a steel strip to form saws
US20070144318A1 (en) * 2005-12-22 2007-06-28 Fu-Zin Agriculture Supply Inc. Method and apparatus for automatically forming teeth of a straight saw

Similar Documents

Publication Publication Date Title
US2047021A (en) Trimmer
US2597648A (en) Machine for forming cutters
US1372738A (en) Method and machine for forming teeth in saws
US2227491A (en) Machine for cutting gears
US2660929A (en) Method of shaving gears
US2329879A (en) Method and machine for generating saw teeth
US3115064A (en) Gear shaving machine
US3479479A (en) Quick-change tool for spark cutting apparatus
US2220182A (en) Apparatus for preparing skelp for welding
US1376861A (en) Universal duplex milling-machine
DE513327C (en) Process for the production of, in particular disk-shaped, bodies delimited by cycloidal curves
US2201500A (en) Machine tool
US2161269A (en) Machine for slotting cutter bodies
US3369433A (en) Apparatus for cutting transverse notches in a belt end
US1896199A (en) Apparatus for the production of files and file casings
US2508534A (en) Material working machine
US1731481A (en) Method of and machine for relieving cutters
US1607193A (en) Deckling machine
US1725246A (en) Method of making thread dies
US1908262A (en) Multiple cutter milling machine
US2851930A (en) Internal gear generator
US907011A (en) Paper-box-blank-making machine.
US1219813A (en) Metal-working machine.
US2292647A (en) Cutter holder
US1482621A (en) Screw and gear making machine